How do we determine the ultimate radioactive decay product of the uranium-238 series is lead?
How do we determine the ultimate radioactive decay product of the uranium-238 series is lead?
You are dating Moon rocks based on their proportions of uranium-238 (half-life of about 4.5 billion years) and its ultimate decay product, lead. a)Find the age for a rock for which you determine that 59% of the original uranium-238 remains, while the other 41% has decayed into lead. b)Find the age for a rock for which you determine that 71% of the original uranium-238 remains, while the other 29% has decayed into lead.
A uranium nucleus (mass 238 u), initially at rest, undergoes a radioactive decay. After an alpha particle ( mass 4.0 u) is emitted, the remaining nucleus is thorium (mass 234 u). If the alpha particle is moving at 0.050 times the speed of light, what is the recoil speed of the thorium nucleus?
A uranium-238 nucleus at rest undergoes radioactive decay, splitting into an alpha particle (helium nucleus) with mass 6.64×10-27 kg and a thorium nucleus with mass 3.89×10-25 kg. The measured kinetic energy of the alpha particle is 4.49×10-13 J. After the decay, what is the magnitude of the momentum of the thorium nucleus? Incorrect. Tries 1/20 Previous Tries After the decay, what is the kinetic energy of the thorium nucleus? 7.664×10-15 J You are correct. Your receipt no. is 158-4017
Write nuclear equations showing how uranium-238 is converted to fissionable plutonium-239. beta decay of uranium-239
Part A A rock contains 0.102 mg of lead-206 for each milligram of uranium-238. The half-life for the decay of uranium-238 to lead-206 is 4.5 109 yr. The rock was formed years ago. 5.02. 108 3.81 108 7.23.108 4.59 108 5.49. 108 Request Answer Submit If we start with 1.000 g of strontium-90, 0.887 g will remain after 5.00 yr. This means that the half-life of strontium-90 is yг. 28.8 4.43 41.6 3.91 5.64 Request Answer Submit
Uranium-238 has 20% alpha decay and 80% beta decay. Its overall half life is 1 hour. What is the half life for the alpha decay. (These numbers are completely made up. I'm just trying to understand how to do these types of questions)
Applications of radioactive decay extend beyond potential terrorism. There are a number of regularly used practical applications. One such application is to use radioactive decay as a mechanism for determining the age of a sample of bones, rocks, meteorites, etc. Say you area scientist tasked with analyzing samples of moon rocks. Your moon rock contains small amounts of Uranium-238. U-238 decays into lead-206 with a half-life of 4.5 billion years. How old is your rock if 55.0% of the original...
(d) Due to alpha decay, l mole of uranium-238 produces 2.96 106 alpha particles per second. Find the half-life, giving your answer in units of years. [5 marks] (e) The average mass of the atoms in a 0.100 kg block of pure carbon is 12.01 u. A small fraction of the atoms are radioactive, with a decay constant of 3.90 x 10-12s. If the activity of the carbon block is 97.8 Bq, calculate what fraction of the atoms are radioactive...
Determine the age of a rock containing 0.065 g of uranium-238 (112 = 4.5 x 10° yr) and 0.046 g of lead–206. (Assume all the lead-206 came from 238U decay.) Enter your answer in scientific notation. x 10 years old
The half-life for the radioactive decay of U−238 is 4.5 billion years and is independent of initial concentration. 1.How long will it take for 10% of the U−238 atoms in a sample of U−238 to decay? 2.If a sample of U−238 initially contained 1.9×1018 atoms when the universe was formed 13.8 billion years ago, how many U−238 atoms will it contain today?